Electric pulse code modulation system of communication



J1me 1953 c. c. EAGLESFIELD 2,640,965

' ELECTRIC PULSE cons MODULATION SYSTEM, OF COMMUNICATION Original Filed 00%. 20, 1949 9 Sheets-Sheet 1 FIG].

W I LOW 30 Inventor QC. EAGLESFI EL D Attorney June 2, 1953 C. C. EAGLESFIELD ELECTRIC PULSE CODE MODULATION SYSTEM OF COMMUNICATION Original Filed Oct. 20, 1949 9 Shets-Sheet 5 FIGS.

DELA Y W- NETWORK 99 F/ G. 7. 9Cg- SHAPER Inventor C.C.EAGLESFI ELD Attorney June 2, 1953 c. c. EAGLESFIELD 2,640,955

ELECTRIC PULSE CODE MODULATION SYSTEM OF COMMUNICATION Original Filed Oct. 20, 1949 9 Sheets-Sheet 4 k "1% 8 Q WWHi- G g I P Q N Q a w u K .L {B T \D o\ x Q) k S K S S R \"1 V) N a; l E Q I \1 Q k g s \w r-W- S I\ u 3 5 .E

Inventor Altorne y June 2, 1953 I cl c. EAGLESFIELD Y 2,640,955

ELECTRIC PULSE CODE MODULATION SYSTEM OF COMMUNICATION Original Filed Oct. 20, 1949 9 Sheets-Sheet 5 38 10s 4/ F/G. 8. PULSE I lg Q) W -ACCEPTOR M 65 43 I09 /O6 v 1/4 N 5-" DELAY v PULSE AFCEPTOR I-4 W CIRCUIT [VERA 52 I M 1/0 I07 DP 9%" us -Ac'c p -o DELAY PULSE M c/kcuif Y 6mme sa I be r //I I T l/6 ACCEPTOR DELAY PULSE C/RCu/T savm' 9P -ACCEPTOR 9H 55 l -ACCEPTOR I uJ v A? AcE/ ro/? -I F H -AccEPToR Inventor C.C.EAGLESF| E LD Attorney June 2, 1953 c. c. EAGLESFIELD 2,640,955

ELECTRIC PULSE CODE MODULATION SYSTEM OF COMMUNICATION Original Filed Oct; 20, 1949 9 Sheets-Sheet 6 M35 //8 v ssnmro Fl G. 9. 7

[/7 DELAY NETWOEK GATE GATE I25 I26 I27 /snmw M I28 129 [so 7 I32 V AMP lF/'R A mrcw 'A 'NTEGMTOR 5-: I35 I39 :W/TCH AMPLIFIER I L gmrc CHAN. 8 mm? 136 I44 r j v SWITCH or [33 M v swlrch c/M G INTEGRATGQ 7 145 f f gwlTcH L AMPLIFIER snare/1! D nwremrop Inventor QC. EAG LESFI ELD Attorney June 2, 1953 c. c. EAGLESFIELD 2,640,965

ELECTRIC PULSE CODE MODULATION SYSTEM 0? COMMUNICATION Original Filed Oct. 20, 19 1s 9 Shets-Sheet 7 F/GJO- GATE PASS

5 I9 19/ Kkcnvso m n F/ G. /4. PUlSE' C005 J GROUP \9) :2 4 ourpuz has wrpur J93 i 94 OUTPUT [28 95 I 0F 29 I v I30 I v Inventor C.C.EAGLESF l ELD Attorney June 2, 1953 c. c. EAGLESFIELD 2,640,965

ELECTRIC PULSE CODE MODULATION SYSTEM OF COMMUNICATION Original Filed Oct. 20, 1949 9 Sheets-Sheet 9 FIG. /5.

5 OUTPUT Fem DIFFERENT/A TING c/ncu/r /97 1 19s a n U c r/ p r m 20/ m9 1 202 ourpur flea/4 R/Naae CIRCUITS -fi goo 221 322 226 A FL+ a T i i .1

D f r 1 J I urn/ 7:0; ACCEPT 7 A B I L 0 v /S 2/8 22 7 4 ourpur ra LINE 5/? v 20 a f 2/9 2 2 228 ULJL n 1L v M m nl'nn nwvr r T: 471 v 2 5 m A r L 1 22C 229 8 L L! c D nl' I Inventor (LC. EA 6 LESFI ELD A Home y Patented June 2, 1953 ELECTRIC PULSE CODE MODULATION SYSTEM OF COMIVIUNICATION Charles Cecil Eaglesfield, London, England, assignor to International Standard Electric Corporation, New York, N. Y., a corporation of Delaware Original application October 20, 1949, Serial No. 122,385. Divided and this application October 31, 1951, Serial No. 254,362. In Great Britain October 22, 1948 4 Claims.

The present invention relates to electric pulse code modulation systems of communication.

This application is a division of my prior application Serial No. 122,385, filed October 20, 1949.

Electric pulse code modulation systems hitherto proposed, have been based on the principle of periodically scanning a signal wave in order to determine at regular intervals its amplitude to the nearest step of a scale of amplitudes havin a finite number of steps. The corresponding step number is then coded and transmitted to the receiving end by a code group of pulses, and the signal amplitude is built up at the receiver from the coded information obtained from the pulses. This system has a better signal-to-noise ratio than pulse systems in which the information is conveyed by variation in amplitude or timing of the pulses, because the receiver generally only has to recognise the presence or absence of a pulse (or at least it has only to distinguish between a very few different pulse amplitudes) so that noise does not interfere with the reception to the same extent as in the other pulse systems. The ad vantage is, of course, secured at the expense of a small amount of signal distortion which results from the use of an amplitude scale with a finite number of steps.

In some of these systems the code groups sent out represent the changes in the signal amplitude rather than the absolute values, so that if the amplitude change is less than some specified amount no code group will be sent out.

In-all of these systems, however, the pulse code groups are controlled by a periodic generator or by some equivalent arrangement which defines regularly spaced instants at which code groups or pulses may be sent out, although as already stated, in some systems code groups or pulses may not be transmitted at some of these instants. Usually also in these known systems the periodic generator controls the instants at which the signal wave is effectively scanned in order to determine the amplitude with reference to the stepped scale.

The present invention is in principle similar to the above mentioned systems in so far as an amplitude scale having a finite number of steps is used; and in so far as a pulse code is used to convey information as to the signal amplitude; but it differs fundamentally from all these systems in this, that there is nothing periodic either in relation to the scanning of the signal wave or in relation to the instants at which the pulse codes are transmitted. The code groups of pulses are 2 sent out at times determined primarily by the times at which the signal amplitude happens to cross the boundaries between the steps of the amplitude scale, and such times occur in general at irregular intervals and do not exhibit any periodic characteristics.

It is known that conventional pulse code modulation systems give an improvement in signalto-noise ratio and that the improvement is greater the more pulses there are in the code, the system of the present invention gives an improvement of about the same order, but there is rather a difference in the possible effects of noise; and a false signal could only make a change of one amplitude step.

Having described the invention in general terms, and explained its relation to the known pulse code modulation systems, it can now be stated that the invention provides according to its principal feature, an electric pulse code modulation system of communication comprising means for setting up an amplitude scale having a finite number of discrete steps, means operative upon a change in the signal amplitude which crosses the boundary between one step of the scale to the next, for generating a pulse code indicating whether the change is an increase or a decrease of amplitude, a receiver, and means for transmitting the pulse code over a communication medium to the receiver, the said receiver comprising means controlled by the received pulse codefor reconstituting the signal wave.

The invention also covers an electric pulse code generator comprising a cathode ray tube having a target plate having two parallel edges, the width of which plate changes progressively in discontinuous steps from one edge of the plate to the opposite edge, means for causing the cathode ray to produce a fine line across the plate parallel to the said edges, means for applying a signal wave to deflect the beam in a direction perpendioular to the said edges, means for deriving a stepped wave from the said plate, means controlled by the stepped wave for generating a pulse code of one type in response to an increase in the amplitude of the stepped wave, and means controlled by the stepped wave for generating a pulse code of a different type in response to a decrease in the amplitude of the stepped wave.

The invention will be described with reference to the accompanying drawings, in which:

Fig. l is a schematic circuit diagram of a simple form of pulse code transmitter for a system according to the invention;

Fig. 2 is a detail of a cathode ray tube used in Fig. 1;

Fig. 3 is a schematic circuit diagram of a simple integrator for reconstituting the signal wave at the receiver from the code pulses;

Fig. 4 is a block schematic circuit diagram of the transmitting terminal of a multichannel pulse code modulation system according to the invention;

Fig. 5 is a schematic circuit diagram of an example of a pulse discriminator usedin Fig. 4;

Fig. 6 is a schematic circuit diagram of an example of the ringer and acceptor circuit of Fig. 4;

Fig. 7 is a detailed diagram of one form of a simple coder which may be used in-Fig. 4;

Fig. 8 is a diagram of a modification of Fig. 4;

Fig. 9 is a block schematic circuit diagram of the receiving terminal of the system;

Fig. 10 is a schematic circuit diagrammtan example of a gating circuit used in Fig. 9;

1 Y Figs, 1 1 is a: schematic circuit; diagram of; an

example of; an electronic switch;used in Fig. 12 is a schematicgcircuit diagram, of an,

example of an integrating circuit used in Fig. 9; and

Figs. l3, l4 and 15 are pulse diagrams used in explaining the operation of the system.

Figs. 1, 2 and 3 disclose an application of the invention probably its simplestform, to a single communication channel. -In Fig-H1 is tube includes a cathode 2 which is the source of.

the electron beam, the usual set orlour deflecting plates 3, I, 5 and 6: (which are shown turned through 90 from'their usualrpositions inlthe tube forrclearness) -andi-a -colleotorp-plate Lon which.

the electron beam impinges. This plate has the special shape shown ingFig. .2, which will be explained later; -'-Ihe-tjube.will be'providedwith other suitably polarised electrodes (not shown) for generating and shaping the electron beam according to knownpractice; The "beam should, however,- befocussed to a sharp-and smallspot on the plate I. Thecathode Land-,oneplate l, 6 from each pair of deflecting plates are connected to ground. .The horizontally deflecting plate 5 is connected to groundthrough an-oscillator 8 which operates at a frequency high compared with any frequency in theband of signalirequencies .that have to be. conveyed by the system. This causes the beamtoltracea fine line across thecollector platelw The signal wave .to'be, transmitted isapplied between input terminals 9 and [0, terminal 9. being connected to the yerticallydeflecting ,plate ithro a kin .cp s 'epsqrl Liane terminal I0 being connected to ground. 'rnqpme 3 should preferably be'connected to ound throughahigh resistance [2 The collector-plate 1 is connected to ground through a load resistance l3 'an'd a positive polarising source 14 of suitable potential. The resistance l3 is'shunted by an integrating condenser l3a. The. plate I is also connected to a differentiating circuit consisting of a small series condenser l5 andshunt resistance l6, one terminal of whichis connected to the ground terminal. l0, and the other to :an output terminal H, which is connected to the communication circuit which conveys the code pulses.

The collector plate 1 takes. the Stepped form horizontal steps from top to bottom. When no input signal voltage is applied at terminal 9, the beam should be arranged to trace a horizontal line l8 across the middle of the plate as shown.

A train of pulses will be generated at the plate 1, and their duration will be proportional to the width of the plate where it is crossed by the line l8. These pulses are integrated by the condenser i3a, which will acquire a potential proportional to the pulse duration and therefore to the width of the plate where it is crossed by the beam.

When there is applied to terminal 9 a signal voltage which increases positively from zero, the line 18 traced by the beam will move upwards until it reaches the -next step of the plate, when the potential of condenser l3a will suddenly increase to'a larger value proportional to the width of the plate at that step. As the signal voltage continues to increase, the potential across condenser Ila will increasesuddenly in equal steps eaehrtime the line reachesthe next step of the plate I.;-Likewisc, whenthe signal voltage decreases and passes through zero and. thenincreases negatively, the line l8 willmove downwards across the plate I and each time a step is passed; the potential across condenser 130 will suddenly decrease. in equal .steps.v The potential variation across the condenser 130 ,will evidently be a stepped version of the signal wave,,and the larger the number of steps in the plate I, the more closely will thesignal-wave vbe represented bythe potential variation of condenser Ha.

The time constant, or. the elements: [Lilla should preferably be iustlarge enoughto. smooth out the pulsesgenerated by the plate 1. Thedita Fig. 2 shows ,pnly I v l h in ,l ffor clearness, but in practice it will be necessary to provide a larger number, probably at least 12.

Thediflerentiating circuit l5, IE will supply to terminal, I! ashort positive pulse every time the potential across. condenser l3a, increases by one step, and :a. similar. short negative ,pulse every-time this potentialdecreases. These short differential pulses are transmitted to the re-, ceiver and; indicate when the signal, amplitude changes to a new value on the amplitude scale, andwhetl er this change isa. rise or a fall. From this information, the wave can be approxi mately reconstructed at the receiver, theapproximation beingthe, closer, the larger the number of steps in the amplitude scale employed.

The short positive and. negative differential pulses thus constitute the simplest possible code for delineating thesig'nal wave. It is obvious that- 1! it.is. not desired .to transmit pulses of both signs, theyfcou'ld be converted into corresponding, positive .(or negative). pulses, having two difierent amplitudes; or durations, or into pairs of pulses with different time spacing, or into any other-desired pulsecode.

While Fig.v 2 indicates that the vertical steps of the plate are all equal, so thatthe step of the amplitude scale are equal, this is not necessary, and it may in some cases be desirable to use a logarithmic amplitude scale, with smaller steps for small amplitudes than large amplitudes. The vertical steps of the plate I can thus be varied in height in a logarithmic or in any othermanner.

Fig. 3shows'a simple example of the manner in which the signal wave may be reconstructed at the receiver fromthe information conveyed by shown in Fig. 2, the width decreasing in equal the received positiveand negative .code pulses.

v In Fig. 3 the codepulses areappliedbetween the input terminals 49- and 20; and are applied through a blocking condenser 2| to charge or discharge an'iintegrating condenser 22 through apair ofoppositely directed, parallel connected diodes 23 and 24. These diodes are normally blocked" by correspondingbias sources 25 and 26 of appropriate potential, the'direct current path being completed by the resistances 21 and 28, of. which the resistance 28 should be very high. It-will be 'seen that the path between the condenser 22 and the input terminal I9 is normally blocked by the diodes, and in the absence of any code pulses, the condenser 22 will have discharged itself through the resistance 28. .1 As-soon as thefirst' code pulse arrive at terminal [9, indicating that the signal amplitude has 1 changed from zero by one step, this pulse, if positive, overcomes the bias of the source 26 and passes through the diode 24, giving a small positive charge to the condenser 22. If the first pulse is negative, it passes through the other diode, and givesthe condenser 22 an equal small negative charge. Thus every time the signal amplitude changes by one step, the charge in condenser 22 changes also by one step in the same, direction as the amplitude change, and it will be evident therefore, that the variation of the potential of the condenser 22 will be a stepped version of the original signal wave.

It will be clear that after the disappearance of any code pulse, the condenser 22 cannot dischargeflthrough either diode provided that the bias sources 25 and 2B are both of higher potenti'al than the maximum potential which the condenser 22 can acquire. The condenser 22 can, however, discharge through the resistance 28 and therefore this resistance should be of such a high value as, to produce a time constant with the condenser 22 which is large compared with the period separating any two code pulses. This means that this time constant must be large compared with the period of the lowest frequency component in the signal wave.

The recovered signal wave potential obtained from-the condenser 22 is preferably smoothed out by passage through a low pass filter 29, before being applied to the. output terminals 30 and 3| to which a telephone receiver (not shown) or other suitable receiving device of circuit may be connected. I

Itshould be added that the signal amplitudes should not be so great that the trace I8 (Fig. 2) moves off the plate 1, and although the deflection sensitivity of the cathode ray tube will naturally be designed in accordance with the expected maximum amplitude of the signal wave it is desired to pass, the signal wave through a suitable limiter (notshown) before application to terminal 9, so that any accidental excessive amplitudes will be. limited- It maybe added that in Fig. 1, if desired, the oscillator 8, and the plates 5 and 6 and the con denser I3a may be omitted, andthe electron beam may instead be shaped in the form of an exceedingly thin horizontal blade wide enough to cover the .plate 1 at itsmaximum width. The results obtained will thenbe substantially the same;

It will be understood that any necessary amplifiersmay be; insertedat any desired points of the circuits which have been described. Reference to such amplifiers has been omitted for clearness.

Althoughthe invention is applicable to a single ,channelas just explained with reference to Figs.

6 *1; 2 and '3; itiisof much more valuewhen applied :to 'multirchannel :systems. :The remaining ngures show the invention applied to a four'channel system, but it will be understood that it is not limited to four channels. f

Fig. 4 is a block schematic circuit diagram of a four-channel'stransmitter according to the invention; The apparatusfor each chan'nelis similar, and that'for channel A will be described in detail; The signal wavewill be applied to the channel inputtermi-nal 32' and thence to a stepper and differentiating circuit 33, which may be that described'with reference to Figsul and 2." The short positive and negative code pulses obtained from the output of the circuit 33 are applied to a' di'scriminator circuit 34""which comprises an arrangement of amplitude limiting valves so disto produce a short positive output pulse at an output terminal 35 in response to a posi tive code pulse, and' 'a similar 'short"positive' output pulse ata second'output' terminal 36; in re spouse to a negative code pulse. An" example'of such a discriminating circuit is described here inafter reference to Fig. 5. --The pulse appearing' at terminal 35 none sponas'to increase in the signal amplitude. and is applied to trigger a circuit 31 which'is connected to an acceptor circuit 38. An example of such. circuits 3! and 38 is described hereinafter with reference to Fig. 6. The circuit 31 generates a train of pulses each of which attempts to operate-"the acceptor circuit for-the purpose of transmitting to the line or'other transmission medium a group of code pulses which indicates. that an increase in signal amplitude has occurred in channel A. As will be explained more fully later, the acceptor circuit 38 cannot be operated if one of the acceptor circuits associated with another channel is oper The circuit 31 will accordingly be called a ringer circuit by analogy with. conventional telephone operation, since it is the means by which a request, is made for use of the line for transmitting the corresponding code pulses. The acceptor circuit 38 corresponds. to the telephone operator.

When ,the acceptor circuit 38v responds, it transmits'a pulse over conductor 39 back to the ringer circuit and stops its operation. The ac ceptor. circuit also transmitsa pulse to the coder 40, which generates the appropriate code groups of pulses which. are sent out to the line which will be connected to, the output terminal 4|.

The pulse. appearing at terminal 36 of the discriminator circuit 34 corresponds to a decrease in the signal amplitude. and is applied to a ringer circuit 42 connected to. an acceptor circuit 43 which stops'the ringer over conductor.44, and operates the coder 45. All the devices 42, 43, 44, 45 are respectively the. same as the devices 31, 38, 39 and 40, except that the coder 45 is designed to send out a different code group from the coder 40, signifying that a decrease instead of an increase in signal amplitude has occurred in channel A. x I Channels B, C and D are all equipped with exactly'similar apparatus to channel A, except that the: coders 45m 5! are respectively designed to sendout different codegroups, of pulses respectively characterising increase or decrease of signal amplitude in channels B, C and D, The eight acceptor circuits 38, 43 and 52 ,t0 51 are all coupledtogether by a conduotor 58 by means of which, if any one acceptor circuit has been operated, all the others are prevented from operating. The manner in which this may be done will be explained later.

It is obvious that a large number of different types of pulse code might be used for identitying the channels and the direction of the signal amplitude change. A simple binary code is, however, preferred. Since eight different indications must be transmitted, a code group which consists of from zero to three successive pulses would normally be sufficient. However, since the code groups are transmitted at irregular times, it is necessary to prefix the group with a fourth pulse which corresponds to the essential starting pulse used in the teleprinter code. Thus the code'comprises from one to four closely spaced pulses, there being always a pulse transmitted in the first time position.

The following table gives an example of a binary code which might be used. It is assumed that there are four equally spaced time instants at which a code pulse can occur, which instants are numbered 1. to 4 in the table, and the letter P indicates that a pulse is transmitted at the corresponding instant, the letter indicating no pulses:

Time instant i [Rise r p P p A Wall... P P P 0 Risen" P l O P B {ran P T o 0 Rise.... P O l a P C {Fall. P o r 0 [Rise P O O P D lFull. l P 0 0 0 It is evident that the above code group could be allotted to the channels in any other way.

While a coding arrangment involving a maximum of four pulses is sufficient for a system having four channels, by using five pulses, eight channels could be accommodated by an extension of this code: and sixteen channels could be dealt with by using six pulses, and generally 2 channels would require a code involving (n+2) pulses.

For dealing with more "than four channels, the arrangement of Fig. 4 can be extended by equipping all the additional channels with the same apparatus, the conductor 58 being extended to connect all the acceptor circuits together. All the coders will 01' course be designated to produce codes involving one or more additional pulses.

Fig. shows one form which the pulse discriminator 34 may take. It comprises two'siinilar valves 58 and 59 arranged'as cathode followers and blessed beyond the cut-off by means of a suitable negative source 68 to which the control grids are connected. The operating source of potential (not shown) for the anodes of the valves will be connected to terminals '6! and 62. The positive or negative pulses from the stepper and differentiating circuit 33 (Fig. l) are applied to the input terminals 83 and -64. Terminal 63 is connected directly to the control grid of the valve 59, and through a reversing valve 65 to the control grid of the valve 53. The reversing valve is normally conducting and is suitably biased by means of a convention cathode bias network 56. The auxiliary circuit elements shown in Fig. 5, but not designated, are conventional, and need not be described.

It will be seen that when a positive pulse is applied at terminal 88, the valve 59 will be unblocked, and a positive output pulse will be obtained from terminal 35 connected to the oathode of the valve. The input pulse will be reversed by the valve 65 and will be applied as a negative pulse from the anode to the control grid of valve 58 which is already blocked, and no effeet is produced.

When a negative pulse is applied at terminal 68, it is clear that the valve 59 will be unaffected and no output will be produced at terminal 35; however, the negative pulse, reversed by the valve 65, will unblock the valve 58, and a positive output pulse will this time be obtained from the output terminal 35 connected to the cathode of the valve 58.

Fig. 6 shows details of one possible form of the ringer circuit 31 and acceptor circuit 38 shown in Fig. 4. The ringer circuit is on the left hand side of the dotted line 31 in Fig. 6, and the acceptor circuit is on the right hand side of this line.

The ringer circuit comprises three conventional milt-ivibrator trigger circuits each comprising two cross-connected valves, and arranged in a cascade ring, so that each one on being triggored, triggers the next one. The arrangement, once started, operates continuously until stopped by means which will be explained presently.

The first of the three multivibrators comprises two valves 68 and 69 each having the anode connected through a condenser to the control grid of the other in the well known way. The lefthand valve 68 is biassed well beyond the cutoff point by a suitable source Til connected to the control grid through a resistance 10a, and the right hand valve 69 is given a much smaller bias from a source I! so that it is in a conducting condition. If a positive pulse of suilicicnt amplitude is applied to the control grid of the valve 68, the multi-vibrator can be triggered over into the second condition with the valve 69 cut oil, and it returns to the first condition after a time, depending on the time constant of the condenser and resistances associated with the control grid of the valve 69. A negative pulse having a. duration equal to the time during which the multivibrator remains in the second condition can be obtained from the anode of the valve 68, or a. similar positive pulse from the anode of the valve 69. The multivibrator can alternatively be triggored by a negative pulse applied to the control grid of the valve 69.

The blocks 12 and I3 represent two other multivi'orators arranged in exactly the same way. The anode-of the valve 68 is connected over conductor H to the control grid of the left hand valve (not shown) of the multivibra-tor 12, the anode of which valve is connected by conductor 15 to the control grid of the left hand valve (not shown) of the multivibrator 13. The anode of this last mentioned valve is connected over conductor 16 to the control grid of a gating pentode valve 11 which is blessed to cut on. by the source 18. The suppressor grid of the valve 11 is normallymaintained at about ground potential by the resistance 1-3. The anode of the valve -11 is connectedto the control grid of the right hand valve 69 01' the first multivibrator.

The short positive pulse from the terminal 35 of the discriminator 34 (Fig. l) is applied to terminal 80, which is connected to the control grid of the left hand valve 68 through a. blockingcondenser 80a. This pulse should be of suflicient amplitude to trigger the circuit over "to the other "9 condition whence it returns, generating negative ringer pulse at the anode of the valve 68. The positive going trailing edge of this negative pulse then triggers the multivibrator 72, which generates a second negative pulse, the trailing edge of which triggers the third multivibrator 13 in the same way to generate a. third negative pulse which passes through, and is reversed by thegating valve ll. The negative going trailing edge of the reversed pulse is applied to the control grid of thefright hand valve 69, and triggers the first multivibrator again, and the process is repeated indefinitely. The anode of the valve 69 thus generates a train of positive ringer pulses, which are applied to the acceptor circuit over conductor 8|. Q

- Thethree multivibrators are thus 1 arranged effectively in a ring so that each is triggered by the trailing edge of a pulse generated by thepreceding one in the ring. It will be understood, of course, that according to. the usual practice, the pulse .will' preferably .be .diiferentiated, .the following multivibrator being triggered by thei-differential pulse corresponding to the trailing edge.

The (diiferentiating operation-may conveniently be effected by suitably choosing the time constant of the elements corresponding to a and 80a in each multivibrator so that no-additional elements actually'have to be provided. .1 a 1 In the case of a four-channel system such as that described with reference .to Fig. 4, the negative and positive ringerpulses generated by the valves .68 and .69 might, for example, have a durationof 10 microseconds while those generated by the multivibrators .12 and 13 might for example each be 12 /2 microseconds, making a totalgap of 25 microseconds between any two ringer pulses. J i

:The acceptor circuit consists'of another multivibrator including two-valves 82 and 83 arranged exactly in the same way as the valves 68 and 69, except that a resistance '84 is connected in series with the conductor connecting the cathodeiof the left hand valve 82 to ground, this valve being the one which is normally cut oil. This cathode is also connected to a terminal '35 to which is connected the common conductor 58 which is shown in Fig. 4, as coupling'all the acceptor circuits together. I i

' If noother acceptor circuit has been operated, then a pulse received over conductor 8| will triggerthe acceptor circuit shown in Fig. 6, over to the second condition, and the time constant of the circuit associated with the grid of valve 83 should be chosen so that it remains in this condition for a period slightly longer than the period between two pulses generated by the valve 69; Anegative pulse having this duration is generated by the anode of the valve 82, and is supplied over the resistance 84, and a positive bias potential is accordingly applied to the cathode of the first valve. of everyother. acceptor circuit in Fig. 4

overthe common conductor 58. This'additional bias causes all these acceptor circuits to require a higher triggering voltage and the amplitude of the triggering pulse supplied over conductor 8| should therefore be chosen so that it cannot trigger an acceptor circuit when it has applied to it the extra bias produced by the operation of another acceptor circuit. This ensures that only one code group can be transmitted at a time, and it will be seen that the ringer circuit will make repeated attempts to operate the acceptor circuit until the latter is released by the return to normal of the already operated acceptor circuit.

The anode of the valve 83 will generate a relatively long positive pulse which is differentiated by the circuit comprising the series condenser 86 and the shunt resistance 81, and the unwanted negative differential pulse corresponding to the trailing edge is removed by the rectifier 88 shunting the resistance 81. The positive differential pulse corresponding to the leading edge is supplied tothe output terminal 89 and thence to the coder 40 (Fig. 4). v 1

Itshould be explained that after a multivibrator circuit has returned to 'the first condition after having been triggered, it'remains for'some.

time in' an insensitive condition during which it cannot be triggered again. Three multivibrators are'shown'in the ringer chain'in order to give time foreach to recover before itis'due to be triggered again. Possiblythe third multivibrator 13' might be omitted, or in other circumstances, a fourth onemight be necessary. In any case, the=dura-' tion of thepulse generated by the acceptor should:

be Slightly greater than one complete period 'f operation of theringer, in order to ensure th t the gating valve shall be blocked long enough to be sure of stopping the re-trig'gering pulse from" the output of the last multivibrator in the chain.

in detail all the auxiliary elements shown, butnot designated. It willmerely be stated that the terminals 90 and SI are for the positive and negative terminals of the high tension sourc (not shown) for the'valves in the circuits.

Fig. '7 shows details of a simple forinf or of the coders shown in Fig. 4 Positive pulses, from the corresponding acceptor are supplied at terminal 92 connectedto' a shaping circuit 93 designed to produce a code pulse of therequired, v The shaping circuit" could be a multivibrator similar to one of thosev duration and amplitude.

shown in 'Fig. 6. The positive'pulses fromthe shaper 93 are applied to the input of a delay net-f work 94 of well known type which mayjiorj ex-f ample, consist of a number of similar meshes corral sisting of series inductances and shunt con-j densers. This network is terminatedat the out-, put end'by a resistance 95 equal to the characf- -i teristi'c" impedance of the network, toprevent pulses from being reflected from the end. Three taps 9G, and 98 are provided on the network at, points from which pulses may be obtained delayed,

respectively t1, t2 and t3 microseconds after the input pulses. The undelayed pulses andlthede layed pulses from the taps 96, 51 and Q8 are applied through buffer diodes 99, I00, NH, and): to a common conductor I03 connected to theline terminal '4! (Fig.4); a

Thearrangement of Fig. 7. is suitable for the coder 40 of Fig. 4. which has-to deliver four code it 1 pulses to the linelsee the codetable given earlier in this specification). For the other coders, one or more of the connections to the taps 96, 91 and 08', and the corresponding diodes, will be omitted, according to the table.

Thus for example, in the case of coder 43, which corresponds to a signal amplitude increase in channel C, the diode I and the corresponding connection to tap 96 will be omitted; for coder 41 diodes IM and I02 will be omitted; for coder BI, diodes I00, I01 and I02 will all be omitted.

Preferably, though not essentially, the code pulses will be transmitted at equal time intervals so that t2=2t1, and t3=3t1.

In the arrangement oi Fig. 4, each channel is provided with two separate coders. However, as shown in Fig. 8, the arrangement may be simplified by providing a single coder common to all the channels. Fig. 8 shows the eight acceptor circuits 38., 03 and 52 to; 51 of Fig, 4, it being understood that the apparatus to the left-hand side of these acceptor circuits. is the same asv shown in Fig. 4 and is accordingly omitted.

The. single coder 04. of Fig. 8 comprises. four parallel circuits containing respectively pulse generators. I05, I05, I01 and I08, all of which are alike, and may be similar to the multivibrator comprising the valves 08 and 60 shown in Fig. 6. Each generator should be designed to produce a single pulse in response to each input pulse, having; the desired duration and amplitude for the code pulses. The generators I06, I0! and I08 are preceded by delay devices I09, H0 and III; each of which may be similar to the same multivibrator, which should be designed to produce a negative pulse of suitable duration from the anode of the valve 68, the positive going trailing edge of which triggers the corresponding pulse generator I06, I01 or I08. The pulses produced by the devices I09, H0 and III should have durations t1, t2, and ta.

The pulse generator I05 is not preceded by a delay device, so if the four generators I05, 105, I07 and I08 are all triggered by an acceptor circuit, they will produce four similar code pulses in succession spaced at intervals of ti, (ta-ti) and (t3.t2), These code pulses will be equally spacedif t2=2ti, and t3=3t1.

If the pulse generators are similar to the multivibrator including the valves 68 and 69, the desired positive code pulses may be obtained for the anode of the second valve, and the time constants of the associated condenser and resistance circuits may be chosen to give these pulses the desired duration.v

The output of each of the eight acceptor circuits is connected in parallel to one or more of the four parallel branches of the coder I04, according to the code which is to be sent out. lhus the acceptor circuit 38, which produces a pulse for an amplitude increase on channel A, is connected to all the branches, since four code pulses are required according to the first line of the table given above. The acceptor circuit 52, which produces a pulse for an amplitude decrease on channel D, is connected only to the first branch which contains the generator I05, since only the first code pulse is required in this case.

Likewise, for example, acceptor circuit 55 is connected only to the first and third branches, and acceptor circuit 52 to the first, second and fourth branches, corresponding to an amplitude decrease on channel C, and an amplitude increase on channel B, respectively, according to the table.

In order to prevent all the branches from being permanently connected together all connections from the acceptor circuits include buffer rectifiers such as II'2 which are directed so as to conduct positive pulses from the acceptor circuit to the corresponding branch. The rectiflers. may consist of diodes, for example.

The pulses generated by the four generators I05 to I00 are supplied through buffer rectifiers or diodes I I3, I I4, I I5 and I I6 to the common output terminal II.

It will be understood that when there are more than four channels in the system, so that one or more additional pulses are required for the code, one or more additional taps will be provided in the delay network of Fig. 7 with corresponding buffer diodes, or one or more additional parallel circuits in Fig. 8, similar to the others, but introducing greater delays.

The duration and spacing of the code pulses which should be chosen depends among other considerations on the number of channels to be served. For a four-channel system, the code pulses, might for example, have a duration of 5 microseconds, and be spaced 5 microseconds apart.

The ringer circuits might then be designed to generate pulses having a. duration 0! 10 microseconds spaced 25 microseconds apart, in which case the pulse generated by the acceptor circuit for stopping the ringer should have a duration of about 50 microseconds. This means that adjacent code groups of pulses could not be closer than 50 microseconds.

In Fig. 9 is shown an example of the manner in which the code groupsv of pulses may be used at the receiver to build up the signal waves in each channel. It is necessary to separate the pulses of each code group and to direct them into different channels where they control a system of electronic switches by means of which an activating pulse is directed to the appropriate channel receiving apparatus.

The code group received from the line or other communication medium is applied to an input terminal II'I connected through a pulse separator IIO to the input of a delay network IIO, the output terminals of which are connected to a. terminating resistance I20, equal to the characteristic impedance of the network.

The pulse separator H8 is designed to select the first pulse of each group, excluding the remaining pulses, and to pass it to the delay network. The separator IIO may, for example, consist of a multivibrator similar to that shown in Fig. 6, comprising the valves 00 and 00, a positive output pulse being taken from the anode of the valve 69. As already stated, this type of circuit remains insensitive to a second triggering for a period which depends on the time constant of the circuit connected to the control grid of the valve 60, and this time constant may be chosen so that the multivibrator cannot be triggered again by any of the following pulses of the code group.

The delay network [I9 has four tapping points I2I, I22, I23 and I24, the first three of which are spaced so that eating pulses may be respectively obtained therefrom at times synchronising with the three later code pulses. A fourth still later activating pulse is obtained from the tapping IN.

The gating pulses are respectively applied to three gating circuits I25, I20 and I21, to which the code pulses are also applied directly from terminal III. In this way the three later code pulses, if present, are selected and are separately supplied to corresponding shaping circuits I20,

I24 or the delay network. v "I'hus, if. the three later code. pulses occurat times tntzrand is after the firsti code pulse, and if. the. activatingpulse occurs at a time t4 thereafter, then the-three codepulses obtained from gate circuits I25,.I26 I and I2! should respectively be givencdurations. slightlytin excess of tA-tl), .(t4t2), and (t4-t3) respectively. 1

The lower part of Fig. 9, includes 7 two-way electronic switches connected in pyramid formation. .'.The flrst of these switches I3I is connected to. the ,tapping point I24 and directs the-activating pulse to either of switches I32 and I33. Switches I32 and. I33 directthe activating'pulse toeither of switches .I34.Iand-I35, an'd I36 and I3], respectively. The last fourswitchesrespectively correspond to'the channels A, B, C and D-andzthe two output terminals of each of these switchesare connected to a corresponding channel integrator I38, I39, I40 or .I4I, the upper con;- nection being through Ja pulse inverting amplifier I42, 143, I44 or I45, used to convert the negative activating pulse obtained from the switch into a positive pulse. In the lower connections a negative pulseisrequired. J The: switches are all'normally in the downward -position as indicated. The switch I3I is activated-by the lengthened pulse corresponding to the'second code pulse, switches I32 and 133 are jointly controlledby the lengthened pulse corresponding to the third code pulse; and switches I34, I35, I36 and I31 are jointly controlled by the lengthened pulse corresponding to the fourth code pulse. 1 When a control pulse is applied to anyswitch, it operates it to theupward position. Thusit will be seen that by thetime thatthe' activating pulse reaches the switch I3I,

any of the code pulses which are present will plitudein channel A,'the four switches I 34 to I31 would not be operated, and the'activating pulse would thenbe directed tothe lowerinputterminals of,;the' integrator I39, where it appears as a, negative pulse.

To take another example, if the secondof the four codepulses is missing, indicating an increase of, signal amplitude inchannel, C, then all, the switches except I3I willbeoperated, and the activating. pulsewill be directed through switches I 3,I I 33 and I 36 to the, upper, terminal of. .the inm momo.

Thepulse 4 lengthening or shaping circuits I28,

I2 and I30 can each comprise a multivibrator larto that including thevalves ,68and 69 of :6 with the timeconstants suitably chosen to glv'e pulses of the required duration, the output lses beingtaken from the anode of the valve 69. I

l showsa suitable form for the gating circuits I 25,. I2 6 and I 21. It comprises a pentode valve 3 I46 arranged somewhat similarly tofthe va1ve ll of, Fig. .with the control grid biassed beyond the cut oil by'means of a suitable source If the last code pulse had" been absent, indicating a decrease in signal am- 14 I-'41;.- ;'Positive' pulses from the delay network are appliedlto unblock the valve to producenegative output pulses at the anode.- However, the sup pressor grid is' also lbiassed to a relatively high.

negative potential by a source I48 so that it would normally cut oil the anode currentproduced by an input pulse; The positive gating pulses from thedelaynetwork are applied to the suppressor grid to permitanode currentto flow when an input positive pulse synchronises with the gating pulse, thereby producing: a negative output pulse whichv is applied to the valve 69 0f the lengthening circuit, as ingFig. 6. 4

In Fig. 11 is shown an example'of an electronic switch suitable for the switches I32 to I31 of Fig.

9. -A pentode valve I49 is arranged similarly w thevalve I46.of Fig. 10, except that the screen grid is provided with a load resistance I50 and is connected to an output terminal I5I. The anode is connected to an output terminal I 52-.

The input pulse is in this case applied from the,

pulse-to the control grid of the valve I49, and whenno control pulse'is applied to the suppressor grid, a negative pulse will be obtained from the output terminal I5I connected to the screen grid, since the suppressorjgrid is..negatively: biassed and cuts off the anode current. I Whena' positive control pulse I from the corresponding one of thespace'current toithe anode, and ainegative output pulse will beobtained'from termina 1 I52 instead of from terminal l5l. 1

However, a much smaller negative 1 pulse will also beobtainedfromthe screen grid, at terminal:

I5I, and in order-to cut this oil, a rectifier I55 in series with a blessing source I56 is connected bee; tween terminal I5! and ground. The rectifier. is directed a's shown, so that it will be blocked, '1 when the electrode connected to. terminal I5I is. The source :I 56 has its positive terminal connected to ground so; that it. biasses the rectifier in the conducting di-1 rection. :fThe potential of the source I56. should ,begreater than that of the small negative output. pulse which appears on the screen grid when a,

negative. to the other electrode.

positive control. pulse is applied tothe suppressor grid,. but less thanthat of the large negative out put pulse which appears on the screen gridin the absence of the control pulse. The large pulse will accordingly block the rectifier I55 and will appear. at terminal I5 I, but the small pulse cannotdo this,. andlwill therefore be. shunted away. through the rectifier, and so will be eliminated. 5'

Theterminalsl5l and I52 are respectively the' lower andupperterminals of the switchesshown in block form in Fig. .9. .As positive. pulses ,are,

required to be supplied to the .upperterminalsof the integrators I38. to I 4|, the inverting ampli- The integratingcircuits I38 to I4I may be. as

shown in Fig. 12, which is'a slight modification of Fig. 3. {The m'odificationconsists inreplacing the. input terminal 5. I S by two. inputterminalsasepa j ea set;

sistances. I58=.and I60. replacing the single resist.-.

ance, 21. Theoperationis the same aslbefore, a positive activating pulse inresponsetoa cote group passing through terminal: I 5= andrdiode .24:-

to charge the condenser 22 :positively, and a negative activating pulse in response to a. different code group passing. through. terminal I55; and;

diode 23; tocharge thecondenser negatively, so that the signalwave is built: up inthe condenser exactlyas before, and is smoothed by thelowpass filter 29 and appliedto the telephone circuit con? nected :to terminals 38 and -3I.

Referring again to 9, ifthereare more.

than .four. channels, the. pyramid arrangement of electronic switches willbe extended by. providing.

one or more. additional banks. which will be re.-

spectively controlled by. one or, moreadditional; Corresponding extra taps. will: be

code pulses. provided: on.the.delaynetwork I19.v between the taps I23,and I242 (so that the activatin pulse is always produced after, thelastcodepulse), to-. gether with extragate and shaper-circuits.

Thus. eight additional switches, all controlled by a. fifth codepulsenndconnected-inpairs to.

theswitches I34 .to.I31 will provideior a total of eight. channels: sixteen more switches, controlled bya. sixth. code. pulsewill' provide. for a total of sixteen channels, and generally, 2F" -l, switchescontrolledby. n2; code, pulses will'provide for. atotal of.2n.ohannels.

In order'tomake-clearer the manner. in which thesystem of. Rigs. 4. to. 12, operates thediagramsofrFigs. 13, 14.andz-'have. been prepared,

In-Fig. 13; theoperationsin channel A have been chosen asan example. IncurveIofwFig.

13, there is shownlat; I51: a. portion of thesignal:

wave applied .toterminal- 91(Fig. 1') l of: the stepper circuit 33- (Eig. 4).

atthetoutput.termina1.l5; ,(lfiig. 1) ofrthe-stepperanddifierentiating circuit 3.3,: (Fig. 4) are shown.

by curve isotEig. 1S1 Thefirsttwo.ofl-thesedif f erential 2 pulses. I 6-3: and I 84-. are. positive. corre..

sponding to the. first. two.upward stepsof; the. Thethird differential pulse I85 is,

curve- I 62; negative. corresponding to the. third: downward step of the curveI 6.2-;

Curve 3- shows.thenorrespondii positive output pulses. I65 and i1 obtained at terminal;

of theidiscrirninatingcircuit-34 (Rig. 4) and-the positive output. pulse I68: which. corresponds. to; the negativepulse I65:.and:appears.at the output;

terminal 36.

The pulse I86.-. operates the ringer. circuit. 31; (Fig. 4) and it. is assumed that the correspond-.

ringer. circuite 31= which again produces two pulses ;I 1 I I 3! M01 the same reason.

The pulse. I58, howeve ope ates h nger 42 which finding the acceptor 43 unblocked, gen erates asingle pulse. I13 curvet shqws the cgrresponding mu J ns r lses I 2 and. I imo.- u vtne. acceptor. circuit-x nt nt es p se to the-.pulses. lllicand I11, and themplse; IJQ pro;

The corresponding stepped wave. generated in-. the. condenser. I 3a connected; to .the .plate.1;of-. the cathoderay tube I. (Fig. 1). is shown atv I62. Thedifierential pulses obtained;

' together Curve I9 ShOWs the positive or nega- 18 duced by. the acceptor. circuit 49 in response to thepulse I13.

Curve Ilshowsthegroups I11 and I18-ottour codepulses producedby-thecoder 48in response totheacceptorv pulses I14 and I15 respectively, which correspond to a. rise in the signal. amplitudeof channelcA, according to the first linelof thetablegiven above. The group I19 of three codepulses is produced by the coder 45'. in response to .the pulse I18;from the acceptor 4.8, and corresponds to a fall in. the. signal amplitude of channel A according to the second line of the table.

It willbe notedthatowing to the fact. that the.

pulses I66 and I61 had to wait for the line, the pulse. groups I11 and I18 areboth late, while group I19 is on time.

Curve 1 shows the activatingpulses I80, I8I. and I82 applied to. the. integrator I38: in response to the code groups I11, I18. and I19 respectively. Pulses I88'and IB'I arepositive-and are applied to the upper-terminal I55 (Fig. 12) of the integrator, while pulseIB! isnegative and is appliedto the lower terminal I56.

Curve 8' shows. the stepped wave I88 built up by the. integrator. This is similar to the stepped wave I62:of curve I; but owing to the fact that the pulse groups I11 and I18 wereboth late, the duration of the top step- I84 is less than that of the corresponding top step I85gof-the wave I82. Apart, therefore, from the distortion due-.to the stepping of theoriginalwave, there will be further distortion as a result, of; the jostlingwlth.

some. other channel. Accordingly,- the pulse durations and the minimum separation of adjacent codegroups should'be designed in relation tothe number of channels. tobe served, so that this jostling occurs only rarely.

14' shows. hovwthe codepulses are dealt,

with. at thereceiver. Curve 9;shows a typical code group in which thethird:pulseismissing, andwhich according tothe table signifies an increase of: signal. amplitude on channel B. The first pulse. I85 of the. group produces the three gatingpulses I86, I81 and I and the activatingpulse.I89.shown incurve IlHrom thedelay net-.

work 9' (Fig. 9). Thus the second and fourth code. pulses. I: and I911 are admitted respectively through thegate circuits I25 andv I21by,

the gating pulses I881and I881and appear'seperately. as shown at I92 and. I93; in. curve II. There. being. no third. code'pulse, there will be no output from the. gating circuit I26. The

lengthened pulses correspondingto I92' and I93 which the code groups for all four channelsare dealt with whenall the channelsareoperating tive; pulses which. are assumed to beproduced atthe outputs of, the channel stepper and differentiating circuits-such as, (Fig. 4). The timingci these pulses hasbeenspecially, chosen toexhibit someof the possible jostling, effects which may occur. Thus amplitudeincreases in channels. A, B, C and. D. are indicated by the,

positive; pulses. I96, I91, I9 8.and I99, and decream on, channels A and-Chit sa ve pulses.

17 20 and 20L It will be noticedthat the pulses I91, 20I and I99 come close together in time.

Curves I4, I and I6 respectively show. the pulses produced by the corresponding ringer circuits, acceptor circuits and coders of Fig. 4, while curve I! shows the pulses applied to the integratorsi in Fig.1p9 by the, last bank ofv switches I34 to I31.

The puls'e I99 (curve I3, FigLllE) causes the ringer; 31 to channel A (Fig.4) to produce. the single; pulse 202, since the line is unoccupied: the acceptor 38 produces the longer pulse 203 and operates the coder 40 to generate the four code pulses 204. A corresponding positive pulse 205 will be applied to the integrator I38 of Fig. 9. Pulse I 9'! (curve I3, Fig. 15) produces in turn the pulses 206, 201, 208 and 209, since the acceptor 38 (Fig. 4) will have completed its operation before the acceptor 52 is due tobe operated.

However, pulse 20I finds the corresponding acceptor 55 blocked because the acceptor 52 is still operated, so the corresponding channel C ringer starts generating a train of pulses 2I0 to 2I3. Curve I4, however, the pulse I99 arrives in channel D between the pulses 2 I0 and 2| I and finding that the channel B acceptor 52 has completed its operation, gets the line first and so the pulse 2II finds the corresponding acceptor 55 blocked again and the ringer has to generate two more pulses 2I2 and 2I3 before it finds the acceptor 55 unblocked.

The pulse I99 causes the corresponding ringer to generate the pulse 2| 4, and the acceptor 56 produces the pulse 2I5 and operates the coder 50 to produce the code group 2I6. The corresponding input pulse to the integrator I4I (Fig. 9) is 2I1.

From curve I5 of Fig. 15 it can be seen that the acceptor pulse '2I5 does not terminate until after the third ringer pulse 2I2 is produced in channel C, so that the fourth pulse 2I3 can now operate the acceptor 55, which produces the longer pulse 2I8 and operates the coder 49 to produce the code group 2 I9, in response to which the negative pulse 220 is applied to the integrator I40 (Fig.9).

It will now be seen from curves I5 and I3 of Fig. 15, that the pulse 2I8 overlaps the negative pulse 200 in channel A. The corresponding ringer 42 thus has to generate two pulses HI and 222 before it finds the acceptor 43 unblocked, which then produces in turn the pulses 223, 224 and 225 as before.

The pulse I98 in channel C arrives after the acceptor 42 ha completed its operation, and so the pulses 226, 221, 228 and 229 are produced without delay, as previously explained.

It will be seen that on account of the interference of the pulses I91 and 20I, the code group 2I9 is delayed by three ringer periods, and because this code group is late it causes the code group 224 also to be late by one ringer period.

It will be clear from these explanations that although the time intervals between the code pulses of any group are specified, the time at which the first pulse is transmitted is determined by the signal amplitude changes.

It should be mentioned that owing to the irregular transmission of the code groups of pulses, there may tend to be a variation in the amplitudes of the pulses due to the effects of the various condensers through which they pass. Such variations may be removed, if desired, by the use of suitable amplitude limiting arrangements before the code pulses are transmitted over the line or other transmission medium.

' It may be added that the multivibrators .12 and 13 shown in Fig. 6' might be replacedbya passive delay network (not shown) of conventional type, and designed"tonintroduce .such a delay that the pulses generated by theimultivibrator 68, 69 have the desired repetition frequency. If this network does not produce can inversion of the pulses, its input terminal should be connected to the anode of the valveIiQ ins stead of to the anode of-thevalve-69. J/ arious other modifications within the scopeor'the invention are evidently possible.

While the principles of the invention have been described above in connection with specific embodiments and particular modifications thereof, it is to be clearly understood that this description is made only by way of example and not as a limitation on the scope of the invention.

What is claimed is:

1. An electric pulse code generator comprising a cathode ray tube having a target plate having two parallel edges, the width of which plate changes progressively in discontinuous steps from one edge of the plate to the opposite edge, means for causing the cathode ray to produce a fine line across the plate parallel to the said edges, means for applying a signal wave to deflect the beam in a direction perpendicular to the said edges, means for deriving a stepped wave from the said plate, means controlled by the stepped wave for generating a code pulse of one type in response to an increase in the amplitude of the stepped wave, and means controlled by the stepped wave for generating a code pulse of a difierent type in response to a decrease in the amplitude of the stepped wave.

2. In an electrical transmission system for transmitting a signal wave, means controlled by the signal wave to be transmitted for generating a corresponding stepped wave in which a change in amplitude occurs each time the signal wave crosses the boundary between the steps of a predetermined amplitude scale having a limited number of discrete steps, means responsive to each change of one step in the amplitude of said stepped wave for producing a pulse, said means comprising means responsive to an increase of one step in the amplitude of the stepped wave for producing a pulse of one type, means responsive to a decrease of one step in the amplitude of the stepped wave for producing a pulse of another type and means responsive to said pulse of one type for producing a first multi-element pulse code signal and means responsive to said pulse of another type for producing a second multi-element pulse code signal.

3. In an lelectrical transmission system for transmitting a signal wave, means controlled by the signal wave to be transmitted for generating a corresponding stepped wave in which a change in amplitude occurs each time the signal wave crosses the boundary between the steps of a predetermined amplitude scale having a limited number of discrete steps, means responsive to an increase of one step in the amplitude of the stepped wave for producinga first multi-element pulse code signal and means responsive to a decrease of one step in the amplitude of said stepped wave for producing a second multi-element pulse code signal.

4. An electric pulse code generator comprising a cathode ray tube having a target plate having two parallel edges, the width of which plate changes progressively in discontinuous steps 19' from one edge of. the plate to the opposite edge, means for causing the cathode ray to produce a fine line across the plate parallel to the said edges, means for applying a signal Wave to deflect the beam in a direction perpendicular to the said edges, means for deriving a stepped wave from the said plate, means responsive to each change of one step in the amplitude of said stepped wave for producing a pulse, said means comprising means responsive to an increase of, one step in the amplitude of the stepped wave for producing 10 Number 20 a pulse of one type, and means responsive to a decreaae of one step in the amplitude 01 the stepped wave for producing a pulse of another type.

CHARLES CECIL EAGLESFIELDv References Cited in the file of this patent UNITED STATES PATENTS Name Date 2,596,149 Hilferty May 13, 1952 

